Modeling Chemical Reactors I: Quiescent Reactors

Abstract

We introduce a fully generalized quiescent chemical reactor system in arbitrary space =1,2 or 3, with n∈N chemical constituents αi, where the character of the numerical solution is strongly determined by the relative scaling between the local reactivity of species αi and the local functional diffusivity Dij(α) of the reaction mixture. We develop an operator time-splitting predictor multi-corrector RK--LDG scheme, and utilize hp-adaptivity relying only on the entropy SR of the reactive system R. This condition preserves these bounded nonlinear entropy functionals as a necessarily enforced stability condition on the coupled system. We apply this scheme to a number of application problems in chemical kinetics; including a difficult classical problem arising in nonequilibrium thermodynamics known as the Belousov-Zhabotinskii reaction where we utilize a concentration-dependent diffusivity tensor Dij(α), in addition to solving a simple equilibrium problem in order to evaluate the numerical error behavior.